Gene and expression
The human ''ERBB3'' gene is located on the long arm of chromosome 12 (12q13). It is encoded by 23,651 base pairs and translates into 1342 amino acids. During human development, ''ERBB3'' is expressed in skin, bone, muscle, nervous system, heart, lungs, and intestinal epithelium. ''ERBB3'' is expressed in normal adult human gastrointestinal tract, reproductive system, skin, nervous system, urinary tract, and endocrine system.Structure
ErbB3, like the other members of the ErbB receptor tyrosine kinase family, consists of an extracellular domain, a transmembrane domain, and an intracellular domain. The extracellular domain contains four subdomains (I-IV). Subdomains I and III are leucine-rich and are primarily involved in ligand binding. Subdomains II and IV are cysteine-rich and most likely contribute to protein conformation and stability through the formation of disulfide bonds. Subdomain II also contains the dimerization loop required for dimer formation. The cytoplasmic domain contains a juxtamembrane segment, a kinase domain, and a C-terminal domain. Unliganded receptor adopts a conformation that inhibits dimerization. Binding of neuregulin to the ligand binding subdomains (I and III) induces a conformational change in ErbB3 that causes the protrusion of the dimerization loop in subdomain II, activating the protein for dimerization.Function
ErbB3 has been shown to bind the ligands heregulin and NRG-2. Ligand binding causes a change in conformation that allows for dimerization, phosphorylation, and activation of signal transduction. ErbB3 can heterodimerize with any of the other three ErbB family members. The theoretical ErbB3 homodimer would be non-functional because the kinase-impaired protein requires transphosphorylation by its binding partner to be active. Unlike the other ErbB receptor tyrosine kinase family members which are activated through autophosphorylation upon ligand binding, ErbB3 was found to be kinase impaired, having only 1/1000 the autophosphorylation activity of EGFR and no ability to phosphorylate other proteins. Therefore, ErbB3 must act as anInteraction with ErbB2
The ErbB2-ErbB3 dimer is considered the most active of the possible ErbB dimers, in part because ErbB2 is the preferred dimerization partner of all the ErbB family members, and ErbB3 is the preferred partner of ErbB2. This heterodimer conformation allows the signaling complex to activate multiple pathways including the MAPK, PI3K/Akt, and PLCγ. There is also evidence that the ErbB2-ErbB3 heterodimer can bind and be activated by EGF-like ligands.Activation of the
Role in cancer
While no evidence has been found that ErbB3 overexpression, constitutive activation, or mutation alone is oncogenic, the protein as a heterodimerization partner, most critically with ErbB2, is implicated in growth, proliferation, chemotherapeutic resistance, and the promotion of invasion and metastasis. ErbB3 is associated with targeted therapeutic resistance in numerous cancers including resistance to: * HER2 inhibitors in HER2+ breast cancers * anti-estrogen therapy in ER+ breast cancers * EGFR inhibitors in lung and head and neck cancers * hormones in prostate cancers * IGF1R inhibitors in hepatomas * BRAF inhibitors in melanoma ErbB2 overexpression may promote the formation of active heterodimers with ErbB3 and other ErbB family members without the need for ligand binding, resulting in weak but constitutive signaling activity.Role in normal development
''ERBB3'' is expressed in theSee also
*References
Further reading
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